Early development of bacteriophages SP01 and SP82G in minicells of Bacillus subtilis.

SP01- and SP82G-infected Bacillus subtilis CU403 divIVBI minicells synthesize 13 easily detectable early RNA species with molecular weights ranging from 60 × 10³ to 430 × 10³. Comparison of in vivo and in vitro translation of early messenger RNA indicates that five early mRNAs of SP01 are synthesized but not translated unless protein synthesis has been permitted in the infected minicell, providing evidence for a translation control mechanism. A sequential appearance of 48 polypeptides has been determined in SP01-infected minicells. The polypeptides have been grouped into two classes of early polypeptides, i.e. those encoded by early mRNA and three subsequent classes as demonstrated by the analysis of polypeptides synthesized in minicells infected with the SP01 mutants, susF21, susF4 and susF14. Phage capsid proteins are not synthesized in minicells. RNA synthesized in infected minicells is subject to turnover. The individual mRNA species have differing functional stabilities ranging from a loss of only 50% functional activity, in 20 minutes at 37 °C, to loss of over 99% activity.Infection of anucleate minicells has been shown to be a very simple method for comparison of closely related phages (slight differences are detected between SP01- and SP82G-encoded mRNA and polypeptides), detection of polypeptides affected by amber mutations and the analysis of early events in phage development in the absence of host syntheses.     

Identification and Properties of the Messenger RNA Activity in Chlamydomonas reinhardi Coding for the Large Subunit of d-ribulose-1,5-bisphosphate Carboxylase

Properties of the mRNA coding for the large subunit of ribulose-1,5-bisphosphate carboxylase from Chlamydomonas reinhardi were determined. Large subunit synthesis, directed by RNA from partially purified whole cell extracts, was detected by specific immunoprecipitation of polypeptide products synthesized in a heterologous translation system derived from Escherichia coli. Large subunit synthesis showed sharp RNA concentration dependence in an E. coli translation system, and at optimal RNA concentrations, immunoprecipitable large subunit synthesis accounted for 2% of the total incorporation. Large subunit messenger activity sedimented at 12 to 14S on nondenaturing sucrose gradients and did not bind to oligo(dT)-cellulose suggesting the mRNA is not polyadenylated. The immunoprecipitable products translated in vitro are not complete polypeptide chains, but are smaller peptides identifiable as large subunit fragments by tryptic fingerprint analysis. No immunoprecipitable product was obtained when similar RNA fractions were tested in a wheat germ translation system.     

Selection of repeated sequences of homologous and heterologous DNA during in vitro transcription by maize RNA polymerase

RNA synthesized $\text{in}\text{vitro}$ by maize RNA polymerase II arises in part from repeated DNA sequences, since significant hybridization to the parent DNA occurs with low concentrations of RNA and DNA. Over three times as much “repeated sequence” RNA is transcribed from maize as from calf thymus DNA.     

Post-feeding induction of trypsin in the midgut of Aedes aegypti L. (Diptera: Culicidae) is separable into two cellular phases

The induction of trypsin activity in the midgut of the mosquito, Aedes aegypti, was studied following meals of chicken blood, and several protein and peptide diets. Various concentrations of bovine serum albumin (BSA) in 0.15 M NaCl stimulated trypsin activity, in a similar fashion to the initial increase observed after a normal blood meal. Trypsin synthesis was also initiated when Ae. aegypti were fed on glutaraldehyde cross-linked BSA and on BSA fragments prepared by both pepsin and cyanogen bromide cleavage. Non-soluble proteins, in the form of glutaraldehyde-fixed erythrocyte ghosts, induced a delayed and reduced trypsin response, whilst small peptides from neutralized liver digests did not induce trypsin activity until 8–10 h after feeding. Metabolic inhibitors had varying effects on the post-feeding activity of trypsin stimulated by BSA feeding. Cycloheximide, a peptidyl transferase inhibitor prevented expression of all activity in vivo, whereas α-amanitin (RNA-polymerase inhibitor) did not affect trypsin activity in the first 10 h after feeding. At 20 μg/ml concentration in the diet, actinomycin D (RNA synthesis inhibitor) caused temporary superinduction followed by inhibition of trypsin activity, but at lower concentrations, the later phase of trypsin activity was inhibited. The results suggest that post-feeding induction of trypsin activity in Ae. aegypti is a two-phase process regulated at the midgut cellular level. The first phase of trypsin synthesis is stimulated by soluble proteins of variable molecular weights, and only involves translation of messenger RNA already available within the midgut cells. The second phase is stimulated by small peptides and requires complete synthesis of new mRNA from DNA.     

Interactions of Bacillus subtilis RNA polymerase with subunits determining the specificity of initiation. Sigma and delta peptides can bind simultaneously to core

The Bacillus subtilis RNA polymerase sigma 43 subunit and the phage SP82 encoded 28-kDa peptide are responsible for the binding of RNA polymerase to early and middle SP82 promoters, respectively. The delta peptide enhances the specificity of the interaction of B. subtilis RNA polymerase with these promoters. We have used sedimentation experiments to determine the effect of each of the three specificity factors, delta, sigma, and the 28-kDa peptide, on the binding of the other two factors to RNA polymerase core and the effect of NaCl on these binding equilibria. We show that sigma 43 and the 28-kDa peptide can each bind to RNA polymerase core at the same time as delta. Sigma 43 and the 28-kDa peptide have similar affinities to core at 0.1 M NaCl, but the 28-kDa peptide binds to core-delta more strongly than sigma 43. The implications of these findings with respect to the replacement of sigma 43 by the 28-kDa peptide and the mechanism of promoter search by B. subtilis RNA polymerase are discussed.     

Adenovirus transcription. V. Quantitation of viral RNA sequences in adenovirus 2-infected and transformed cells.

The concentrations, in copies per cell, of viral RNA sequences complementary to different regions of the genome were determined at 8, 18 and 32 hours after infection of human cells with adenovirus type 2: separated strands of fragments of ³²P-labelled adenovirus 2 DNA, generated by cleavage with restriction endonucleases EcoR1, Hpa1 and BamH1, were added to reaction mixtures at sufficient concentrations to drive hybridizations with infected or transformed cell RNA. Under these conditions, the fraction of ³²P-labelled DNA entering hybrid is directly proportional to the absolute amount of complementary RNA in the reaction.At 8 hours after infection in the presence of cytosine arabinoside, “early” viral messenger RNA sequences are present at a frequency of 300 to 1000 copies per cell. The abundance of early mRNA sequences in different lines of adenovirus 2-transformed rat cells is markedly lower than their concentration in lytically infected cells. Moreover, the abundance of early mRNA in a given transformed rat cell line reflects the number of copies of its template DNA sequences per diploid quantity of cell DNA. After the onset of the late phase of the lytic cycle, the abundance of one early mRNA species, that coding for a single-stranded DNA binding protein required for viral DNA replication, is amplified. Viral RNA sequences complementary to regions of the genome coding for other early mRNA sequences remain at the level observed at 8 hours after infection.Exclusively “late” viral mRNA sequences are present over a range of concentrations, 500 to 10,000 copies per cell, depending on the region of the genome. By 18 hours after infection, the nucleus contains approximately three times as much total, viral RNA as the cytoplasm. The abundant nuclear, viral RNA sequences at 18 hours are transcribed from a contiguous region, 65% of the genome in length. In some cases, viral RNA sequences complementary to mRNA sequences are very abundant in the nucleus. When cytoplasmic and nuclear fractions are mixed and incubated under annealing conditions, some mRNA sequences will anneal with more abundant, anti-messenger nuclear RNA sequences to form double-stranded RNA. Such annealing of nuclear, viral RNA to early, cytoplasmic mRNA sequences probably accounts for the inability to detect, by filter hybridization, certain classes of early mRNA sequences during the late stage of infection.     

Polyamines can replace the dialyzable component from crude reticulocyte initiation factors.

The polyamines spermidine and spermine can replace the dialyzable component, previously indicated as “iRNA”, in restoring the activity of dialyzed initiation factors on messenger RNA translation in vitro. These results further sustain our earlier suggestions (1, 2) that the RNA nature of the dialyzable component (3) is questionable.     

The synthesis and turnover of virus-specific polyadenylated RNA in polyoma-infected cells.

Mouse embryo cells infected with the 3049 strain of polyoma virus contain several fold more virus-specific, polyadenylated RNA beginning between 4 and 8 hours after the onset of viral DNA synthesis than do cells infected with wild-type virus (lpS). Following infection with either virus strain, there is an identical small but significant enhancement of the level of total polyadenylated RNA measured by binding of ¹²⁵I-labeled RNA to poly(dT)cellulose. The polyadenylation of “early” virus-specific RNA is inhibited 85–90% by cordycepin resulting in an “early” RNA preparation which competes fully with polyadenylated “early” virus-specific RNA in the ternary complex assay. Utilizing the nonpolyadenylated “early” RNA, competition hybridization demonstrated that approximately 78% of the enlarged pool of “late” 3049 polyadenylated RNA and 72% of the “late” lpS pool consisted of sequences unique to the “late” period. No significant difference in the rate of decay of 3049 and lpS-specific, “late” polyadenylated RNA following actinomycin D block was found. Infection by either strain of polyoma virus did not alter the rate of decay of total polyadenylated RNA.     

In vitro synthesis of RNA with “aggregate” enzyme,chromatin, and DNA from liver of methylazoxymethanol acetate-treated rats

“Aggregate” enzyme, chromatin and DNA preparations were isolated from livers of rats treated with the carcinogen, methylazoxymethanol (MAM) acetate. DNA template activity for RNA synthesis in vitro was unimpaired while the template activity of chromatin was slightly reduced. There was a marked inhibition of UTP incorporation into RNA, however, when the “aggregate” enzyme preparation was the source of both template and RNA polymerase. Circular dichroism analysis of the “aggregate” enzyme preparation indicated a change in conformation of the protein component. The results suggest that MAM acetate interacts with nuclear proteins and produces conformational changes which result in a decreased RNA synthesis.